Inheritance enables us to define a class that takes all the functionality from a parent class and allows us to add more. In this tutorial, you will learn to use inheritance in Python.
Inheritance in Python
Inheritance is a powerful feature in object oriented programming.
It refers to defining a new class with little or no modification to an existing class. The new class is called derived (or child) class and the one from which it inherits is called the base (or parent) class.
Python Inheritance Syntax
class BaseClass: Body of base class class DerivedClass(BaseClass): Body of derived class
Derived class inherits features from the base class where new features can be added to it. This results in re-usability of code.
Example of Inheritance in Python
To demonstrate the use of inheritance, let us take an example.
A polygon is a closed figure with 3 or more sides. Say, we have a class called
Polygon defined as follows.
class Polygon: def __init__(self, no_of_sides): self.n = no_of_sides self.sides = [0 for i in range(no_of_sides)] def inputSides(self): self.sides = [float(input("Enter side "+str(i+1)+" : ")) for i in range(self.n)] def dispSides(self): for i in range(self.n): print("Side",i+1,"is",self.sides[i])
This class has data attributes to store the number of sides n and magnitude of each side as a list called sides.
inputSides() method takes in the magnitude of each side and
dispSides() displays these side lengths.
A triangle is a polygon with 3 sides. So, we can create a class called Triangle which inherits from Polygon. This makes all the attributes of Polygon class available to the Triangle class.
We don’t need to define them again (code reusability). Triangle can be defined as follows.
class Triangle(Polygon): def __init__(self): Polygon.__init__(self,3) def findArea(self): a, b, c = self.sides # calculate the semi-perimeter s = (a + b + c) / 2 area = (s*(s-a)*(s-b)*(s-c)) ** 0.5 print('The area of the triangle is %0.2f' %area)
Triangle has a new method
findArea() to find and print the area of the triangle. Here is a sample run.
>>> t = Triangle() >>> t.inputSides() Enter side 1 : 3 Enter side 2 : 5 Enter side 3 : 4 >>> t.dispSides() Side 1 is 3.0 Side 2 is 5.0 Side 3 is 4.0 >>> t.findArea() The area of the triangle is 6.00
We can see that even though we did not define methods like
dispSides() for class
Triangle separately, we were able to use them.
If an attribute is not found in the class itself, the search continues to the base class. This repeats recursively, if the base class is itself derived from other classes.
Method Overriding in Python
In the above example, notice that
__init__() method was defined in both classes, Triangle as well Polygon. When this happens, the method in the derived class overrides that in the base class. This is to say,
__init__() in Triangle gets preference over the
__init__ in Polygon.
Generally when overriding a base method, we tend to extend the definition rather than simply replace it. The same is being done by calling the method in base class from the one in derived class (calling
A better option would be to use the built-in function
super().__init__(3) is equivalent to
Polygon.__init__(self,3) and is preferred. To learn more about the
super() function in Python, visit Python super() function.
Two built-in functions
issubclass() are used to check inheritances.
True if the object is an instance of the class or other classes derived from it. Each and every class in Python inherits from the base class
>>> isinstance(t,Triangle) True >>> isinstance(t,Polygon) True >>> isinstance(t,int) False >>> isinstance(t,object) True
issubclass() is used to check for class inheritance.
>>> issubclass(Polygon,Triangle) False >>> issubclass(Triangle,Polygon) True >>> issubclass(bool,int) True